Construction of Simulation Wavefunctions for Aqueous Species : D

This paper investigates Monte Carlo techniques for construction of compact wavefunctions for the internal atomic motion of the D 3 O + ion. The polarization force field models of Stillinger, et al. and of Ojamae, et al. were used. Initial pair product wavefunctions were obtained from the asymptotic high temperature many-body density matrix after contraction to atom pairs using Metropolis Monte Carlo. Subsequent characterization shows these pair product wavefunctions to be well optimized for atom pair correlations despite that fact that the predicted zero point energies are too high. The pair product wavefunctions are suitable to use within variational Monte Carlo, including excited states, and density matrix Monte Carlo calculations. Together with the pair product wavefunctions, the traditional variational theorem permits identification of wavefunction features with significant potential for further optimization. The most important explicit correlation variable found for the D 3 O + ion was the vector triple product r OD1 ·(r OD2 ×r OD3). Variational Monte Carlo with 9 of such explicitly correlated functions yielded a ground state wavefunction with an error of 5-6% in the zero point energy.